Henley's Twentieth Century Formulas, Recipes and Processes. Various
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I | II | III | |
---|---|---|---|
Silver | 33.3 | 34 | 40.0 |
Copper | 41.8 | 42 | 44.6 |
Nickel | 8.6 | 8 | 4.6 |
Zinc | 16.3 | 16 | 10.8 |
Japanese (Gray) Silver.
—An alloy is prepared in Japan which consists of equal parts of copper and silver, and which is given a beautiful gray color by boiling in a solution of alum, to which copper sulphate and verdigris are added. The so-called “mokum,” also a Japanese alloy, is prepared by placing thin plates of gold, silver, copper, and the alloy just described over each other and stretching them under the hammer. The cross sections of the thin plates obtained in this way show the colors of the different metals, which give them a peculiar striped appearance. Mokum is principally used for decorations upon gold and silver articles.
Silver-zinc.
—Silver and zinc have great affinity for each other, and alloys of these two metals are therefore easily made. The required quantity of zinc, wrapped in paper, is thrown into the melted and strongly heated silver, the mass is thoroughly stirred with an iron rod, and at once poured out into molds. Alloys of silver and zinc can be obtained which are both ductile and flexible. An alloy consisting of 2 parts of zinc and 1 of silver closely resembles silver in color, and is quite ductile. With a larger proportion of zinc the alloy becomes brittle. In preparing the alloy, a somewhat larger quantity of zinc must be taken than the {77} finished alloy is intended to contain, as a small amount always volatilizes.
Imitation Silver Alloys.
—There are a number of alloys, composed of different metals, which resemble silver, and may be briefly mentioned here.
I.—Warne’s metal is composed of tin 10 parts, bismuth 7, and cobalt 3. It is white, fine-grained, but quite difficult to fuse.
II.—Tonca’s metal contains copper 5 parts, nickel 4, tin 1, lead 1, iron 1, zinc 1, antimony 1. It is hard, difficult to fuse, not very ductile, and cannot be recommended.
III.—Trabuk metal contains tin 87.5, nickel 5.5, antimony 5, bismuth 5.
IV.—Tourun-Leonard’s metal is composed of 500 parts of tin and 64 of bell metal.
V.—Silveroid is an alloy of copper, nickel, tin, zinc, and lead.
VI.—Minargent. Copper, 100 parts; nickel, 70 parts; tungsten, 5 parts; aluminum, 1 part.
VII.—Nickel, 23 parts; aluminum, 5 parts; copper, 5 parts; iron, 65 parts; tungsten, 4 parts.
VIII.—Argasoid. Tin, 4.035; lead, 3.544; copper, 55.780; nickel, 13.406; zinc, 23.198; iron, trace.
SOLDERS: See Solders.
Steel Alloys: See Also Steel.
For Locomotive Cylinders.
—This mixture consists of 20 per cent steel castings, old steel springs, etc.; 20 per cent No. 2 coke iron, and 60 per cent scrap. From this it is stated a good solid metal can be obtained, the castings being free from honeycombing, and finishing better than the ordinary cast-iron mixture, over which it has the advantage of 24 per cent greater strength. Its constituents are: Silicon, 1.51; manganese, 0.33; phosphorus, 0.65; sulphur, 0.068; combined carbon, 0.62; graphite, 2.45.
Nickel steel is composed of nickel 36 per cent, steel 64 per cent.
Tungsten steel is crucible steel with 5 to 12 per cent tungsten.
Stereotype Metal.
Lead | 2 parts |
Tin | 3 parts |
Bismuth | 5 parts |
The melting point of this alloy is 196° F. The alloy is rather costly because of the amount of bismuth which it contains. The following mixtures are cheaper:
I | II | III | IV | |
---|---|---|---|---|
Tin | 1 | 3 | 1 | 2 |
Lead | 1 | 5 | 1.5 | 2 |
Bismuth | 2 | 8 | 3 | 5 |
Antimony | — | — | — | 1 |
Tin Alloys:
Alloys For Dentists’ Molds And Dies.
—I.—Very hard. Tin, 16 parts; antimony, 1 part; zinc, 1 part.
II.—Softer than the former. Tin, 8 parts; zinc, 1 part; antimony, 1 part.
III.—Very hard. Tin, 12 parts; antimony, 2 parts; copper, 1 part.
Cadmium Alloy, About The Hardness Of Zinc.
—Tin, 10 parts; antimony, 1 part; cadmium, 1 part.
Tin-lead.
—Tin is one of those metals which is not at all susceptible to the action of acids, while lead, on the other hand, is very easily attacked by them. In such alloys, consequently, used for cooking utensils, the amount of lead must be limited, and should properly not exceed 10 or 15 per cent; but cases have been known in which the so-called tin contained a third part, by weight, of lead.
Alloys containing from 10 to 15 per cent of lead have a beautiful white color, are considerably harder than pure tin, and much cheaper. Many alloys of tin and lead are very lustrous, and are